CN210885825U - Vacuum glass evacuating device - Google Patents

Abstract

The utility model discloses a vacuum glass evacuating device, including engine body shell, combination glass and motor, the sliding chamber has been seted up to engine body shell's top is inside, and the internal connection in sliding chamber has the exhaust duct, the below of exhaust duct is connected with the interior pipeline, and the outside of interior pipeline is provided with outer pipeline, the motor is installed in engine body shell's left side, and installs drive gear above engine body shell's the inside, drive gear's front side is connected with the transmission slide, the lower extreme of interior pipeline is connected with the metal sprue through the connecting block, and the connecting block installs in the top of metal sprue, the injecting glue mouth has been seted up to the bottom of outer pipeline. This vacuum glass evacuating device, staff only need carry out the lift of operation control transmission slide to the motor and can accomplish the evacuation and the sealed processing to vacuum glass, and glue dual function through metal sprue and seal, have prolonged vacuum glass's life.

Description

Vacuum glass evacuating device

Technical Field

The utility model relates to a glass deep-processing technology field for the building specifically is a vacuum glass evacuating device.

Background

The deep processing of the glass for the building is a process of processing common glass into the strength glass which can be used for the building, and compared with the conventional glass for daily life, the glass for the building emphasizes the strength performance of the glass in the production and processing process, and needs to have the performances of light regulation, heat preservation, heat insulation, safety, fire prevention, appearance decoration and the like, wherein the vacuum glass is novel building glass which is developed in recent years and has extremely high heat insulation and protection performance.

Vacuum glass bonds two or multi-disc glass through professional equipment, encapsulates all around, takes away their inside air behind the isolated outside air and forms the vacuum again, thereby realize the isolated performance to heat and radiation, conventional vacuum glass carries out evacuation processing in the high temperature furnace in the packaging process many, however this kind of evacuation mode can't avoid artifical supplementary, needs the staff to seal air exhaust pipeline switch-on and final extraction opening, comparatively consumes artifical material resources.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a vacuum glass evacuating device to the conventional vacuum glass evacuating mode who proposes in solving above-mentioned background art needs artifical supplementary, comparatively consuming time power, the higher problem of cost.

In order to achieve the above object, the utility model provides a following technical scheme: a vacuum glass vacuumizing device comprises a machine body shell, combined glass and a motor, wherein a rotary door is installed in front of the machine body shell, a mounting plate is connected inside the machine body shell, the combined glass is connected above the mounting plate, an air suction port is formed in the upper surface of the combined glass, a sliding cavity is formed inside the upper portion of the machine body shell, an air suction pipeline is connected inside the sliding cavity, an inner pipeline is connected below the air suction pipeline, an outer pipeline is arranged outside the inner pipeline, the left side of the outer pipeline is connected with an adhesive injection pipe, the motor is installed on the left side of the machine body shell, a transmission gear is installed above the inner portion of the machine body shell and is connected with the motor, a transmission sliding plate is connected to the front side of the transmission gear and is connected with the outer pipeline, the lower end of the inner pipeline is connected with a metal block through a connecting block, and the connecting block is arranged above the metal block, and the bottom of the outer pipeline is provided with a glue injection port.

Preferably, the swing door and the inner wall of the body housing form a clamping structure, the body housing and the mounting plate form a sliding structure, and the mounting plate and the combined glass form an integrated structure.

Preferably, the sliding cavity and the air exhaust pipeline form a sliding structure, the air exhaust pipeline, the inner pipeline and the outer pipeline form an integrated structure, and the air exhaust pipeline is arranged to be a foldable coiled structure.

Preferably, the inner pipeline and the air exhaust port form a sliding structure, the inner pipeline and the metal block form a disassembly and assembly structure through the connecting block, the connecting block is made of elastic metal materials, and meanwhile, the connecting position of the connecting block and the inner pipeline is an inclined structure.

Preferably, the bottom of outer pipeline is arranged with the injecting glue mouth with the equal angle, and outer pipeline and injecting glue pipe constitute integrated configuration to the injecting glue pipe sets up to flexible graphite packing material.

Preferably, the transmission gear is engaged with the transmission sliding plate, the transmission sliding plate and the machine body shell form a sliding structure, and the transmission sliding plate and the outer pipeline form an integrated structure.

Preferably, the diameter of the metal block is the same as that of the air extraction opening, and the height of the metal block is smaller than the depth of the air extraction opening.

Compared with the prior art, the beneficial effects of the utility model are that: the vacuum glass vacuumizing device is provided with a vacuum chamber,

1. the device reduces the working difficulty of workers to the maximum extent, the workers do not need to connect the air exhaust pipeline, the inner pipeline and the air exhaust pipeline are controlled by the motor and the transmission gear, so that the inner pipeline and the air exhaust pipeline can be inserted into the air exhaust port without contacting with the workers, air exhaust treatment is carried out on the combined glass, after air exhaust is completed, the device can independently carry out closed treatment on the air exhaust port, the workers only need to control the up-and-down lifting of the inner pipeline and the outer pipeline, and the operation mode is simple and labor-saving;

2. the method is characterized in that the extraction opening is sealed by adopting a double-combination mode of the metal block and the sealing colloid, the metal block is firstly fixed inside the extraction opening after the extraction is finished, then the sealing colloid is continuously poured above the metal block, and a worker can also choose to seal the extraction opening for the third time when taking out the vacuum glass after the sealing is finished, so that the complete sealing of the extraction opening can be ensured, and the service life of the vacuum glass is prolonged;

3. the whole process of bleeding need not staff and glass board and contacts, has reduced the possibility that leaves the fingerprint at the glass inboard in the course of working, has guaranteed the cleanliness of glass face, and can play the guard action to vacuum glass, and the heating environment is located engine body shell's inside, only heats engine body shell's inside, greatly reduced the loss that produces in the heating process, and can not cause the health injury to the staff.

Drawings

FIG. 1 is a schematic view of the overall front view cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the left-side sectional structure of the transmission gear and the transmission slide plate of the present invention;

fig. 3 is an enlarged schematic view of a portion a in fig. 1 according to the present invention.

In the figure: 1. a body housing; 2. a revolving door; 3. an air extraction opening; 4. mounting a plate; 5. combining glass; 6. a sliding cavity; 7. an air extraction pipeline; 8. an inner conduit; 9. an outer conduit; 10. a glue injection pipe; 11. a motor; 12. a transmission gear; 13. a transmission slide plate; 14. connecting blocks; 15. a metal block; 16. and (6) a glue injection port.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a vacuum glass vacuumizing device comprises a machine body shell 1, a revolving door 2, an air exhaust port 3, a mounting plate 4, a combined glass 5, a sliding cavity 6, an air exhaust pipeline 7, an inner pipeline 8, an outer pipeline 9, a glue injection pipe 10, a motor 11, a transmission gear 12, a transmission sliding plate 13, a connecting block 14, a metal blocking block 15 and a glue injection port 16, wherein the revolving door 2 is installed in front of the machine body shell 1, the mounting plate 4 is connected inside the machine body shell 1, the combined glass 5 is connected above the mounting plate 4, the air exhaust port 3 is arranged on the upper surface of the combined glass 5, the sliding cavity 6 is arranged inside the machine body shell 1, the air exhaust pipeline 7 is connected inside the sliding cavity 6, the inner pipeline 8 is connected below the air exhaust pipeline 7, the outer pipeline 9 is arranged outside the inner pipeline 8, the glue injection pipe 10 is connected on the left side of the outer pipeline 9, the motor 11 is installed on the left, and the inside top of organism shell 1 installs drive gear 12 to drive gear 12 and motor 11 interconnect, the front side of drive gear 12 is connected with transmission slide 13, and transmission slide 13 and outer pipeline 9 interconnect, and the lower extreme of interior pipeline 8 is connected with metal sprue 15 through connecting block 14, and connecting block 14 installs in the top of metal sprue 15, and glue injection mouth 16 has been seted up to the bottom of outer pipeline 9.

Revolving door 2 constitutes block structure with engine body shell 1's inner wall, and engine body shell 1 constitutes sliding construction with mounting panel 4 to mounting panel 4 constitutes the integral structure with combination glass 5, seals engine body shell 1's inside through revolving door 2, is favorable to the inside temperature rise of engine body shell 1, and combination glass 5 places in mounting panel 4's top, through mounting panel 4 slidable mounting in engine body shell 1's inside.

Sliding cavity 6 constitutes sliding structure with air exhaust pipeline 7, and air exhaust pipeline 7 all constitutes integral structure with interior pipeline 8 and outer pipeline 9, and air exhaust pipeline 7 sets up to folding convolution, and interior pipeline 8 and outer pipeline 9 can slide from top to bottom in body shell 1's inside, can drive air exhaust pipeline 7 and carry out synchronous motion, therefore air exhaust pipeline 7 sets up to the beta structure that can stretch out and draw back, and can slide in sliding cavity 6's inside, thereby can not influence interior pipeline 8's motion.

Interior pipeline 8 constitutes sliding construction with extraction opening 3, and interior pipeline 8 passes through connecting block 14 and metal sprue 15 constitution dismantles mounting structure, and connecting block 14 sets up to having elastic metal material, connecting block 14 sets up to the slope structure with interior pipeline 8's junction simultaneously, metal sprue 15 passes through connecting block 14 to be fixed in the bottom of interior pipeline 8, carry out synchronous elevating movement along with interior pipeline 8, after finishing bleeding and letting in the viscose through injecting glue mouth 16 to the inner wall of extraction opening 3, interior pipeline 8 drives metal sprue 15 and gets into the inside of extraction opening 3, carry out the shutoff to extraction opening 3, treat that metal sprue 15 and viscose bonding are firm enough, upwards rise interior pipeline 8, connecting block 14 takes place deformation, make metal sprue 15 can break away from the bottom of interior pipeline 8 smoothly and stop in the inside of extraction opening 3.

The bottom equiangular arrangement of outer pipeline 9 has injecting glue mouth 16, and outer pipeline 9 constitutes the integral structure with injecting glue pipe 10, and injecting glue pipe 10 sets up to flexible graphite packing material, flexible graphite packing has high heat resistance, and the material is soft can take place deformation, consequently can let in professional viscose through the inside of injecting glue pipe 10 outside pipeline 9, and can not influence the oscilaltion motion of outer pipeline 9, stop in the inside back of extraction opening 3 when metal sprue 15, continue to hold up the colloid to the inside vacant department of extraction opening 3 through injecting glue mouth 16, ensure to carry out the complete shutoff to extraction opening 3.

The transmission gear 12 is connected with the transmission sliding plate 13 in a meshing manner, the transmission sliding plate 13 and the machine body shell 1 form a sliding structure, the transmission sliding plate 13 and the outer pipeline 9 form an integrated structure, the transmission gear 12 drives the transmission sliding plate 13 to move up and down, so that the inner pipeline 8 and the outer pipeline 9 are driven to move up and down, the inner pipeline 8 is ensured to be contacted with the air exhaust port 3 at a proper time to exhaust the combined glass 5, and the inner pipeline 8 can be lifted to be separated from the air exhaust port 3 after the air exhaust is completed.

The diameter of metal sprue 15 is the same with the diameter of extraction opening 3, and the degree of depth that highly is less than extraction opening 3 of metal sprue 15, and metal sprue 15 constitutes sliding structure with extraction opening 3, can slide in the inside of extraction opening 3 along with interior pipeline 8 is smooth, thereby stop in the inside of extraction opening 3 through the viscose after the completion of bleeding, continue to pour into the colloid in the top of metal sprue 15, the shutoff is glued and is combined with metal sprue 15 and can be ensured the complete shutoff to extraction opening 3.

The working principle is as follows: as shown in fig. 1 and 2, when a worker uses the device to perform vacuum pumping on the bonded combined glass 5, firstly, the combined glass 5 is fixedly placed above the mounting plate 4, the swing door 2 is opened, the mounting plate 4 and the combined glass 5 are pushed into the interior of the machine body shell 1 in a sliding manner, so that the pumping port 3 above the combined glass 5 is positioned right below the inner pipeline 8, the swing door 2 is closed after confirming that the metal block 15 is connected below the inner pipeline 8, the inner protruding part of the swing door 2 is ensured to be mutually clamped with the inner wall of the machine body shell 1, the interior of the machine body shell 1 is heated through the heating device, the motor 11 is started after a specific temperature is reached, the transmission gear 12 is driven to rotate, and the transmission sliding plate 13 drives the inner pipeline 8 and the outer pipeline 9 to perform synchronous motion;

as shown in fig. 1 and 3, the inner pipe 8 and the outer pipe 9 are lowered to make the metal block 15 pass through the pumping hole 3 to enter the inside of the composite glass 5, the other end of the pumping pipe 7 is connected with a pumping device, the pumping device is started to perform vacuum pumping on the composite glass 5 in a high temperature environment, after the pumping is finished for a period of time, the pumping device is closed, a professional colloid is injected into the outer pipe 9 through the glue injection pipe 10, the adhesive flows downwards to leave the inside of the outer pipe 9 through the glue injection hole 16 and adheres to the inner wall of the pumping hole 3, at this time, the inner pipe 8 is lifted upwards through the motor 11, the pumping pipe 7 slides synchronously inside the sliding cavity 6, so that the metal block 15 enters the inside of the pumping hole 3 to be contacted with the adhesive, after the metal block 15 and the adhesive are adhered to each other, the inner pipe 8 is continuously lifted upwards, the connecting block 14 is forced to deform, the inclined structure roll-off inner pipe 8's on top inside, metal sprue 15 breaks away from the block with inner pipe 8 this moment, lets in the bonding colloid to the inside of outer pipeline 9 through injecting glue pipe 10 again, and the colloid falls and deposits in the inside of extraction opening 3 to the top of metal sprue 15 to further implement to seal extraction opening 3, then the evacuation of combination glass 5 is accomplished.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a vacuum glass evacuating device, includes engine body shell (1), combination glass (5) and motor (11), its characterized in that: the refrigerator comprises a refrigerator body shell (1), a revolving door (2) is installed in front of the refrigerator body shell (1), a mounting plate (4) is connected inside the refrigerator body shell (1), combined glass (5) is connected above the mounting plate (4), an air suction port (3) is formed in the upper surface of the combined glass (5), a sliding cavity (6) is formed inside the upper portion of the refrigerator body shell (1), an air suction pipeline (7) is connected inside the sliding cavity (6), an inner pipeline (8) is connected below the air suction pipeline (7), an outer pipeline (9) is arranged outside the inner pipeline (8), an adhesive injection pipe (10) is connected to the left side of the outer pipeline (9), a motor (11) is installed on the left side of the refrigerator body shell (1), a transmission gear (12) is installed above the inner portion of the refrigerator body shell (1), and the transmission gear (12) is connected with the motor (11, the front side of the transmission gear (12) is connected with a transmission sliding plate (13), the transmission sliding plate (13) is connected with the outer pipeline (9) in an interconnecting mode, the lower end of the inner pipeline (8) is connected with a metal plugging block (15) through a connecting block (14), the connecting block (14) is installed above the metal plugging block (15), and a glue injection port (16) is formed in the bottom of the outer pipeline (9).

2. A vacuum glass evacuation device as claimed in claim 1, wherein: the swing door (2) and the inner wall of the machine body shell (1) form a clamping structure, the machine body shell (1) and the mounting plate (4) form a sliding structure, and the mounting plate (4) and the combined glass (5) form an integrated structure.

3. A vacuum glass evacuation device as claimed in claim 1, wherein: the sliding cavity (6) and the air exhaust pipeline (7) form a sliding structure, the air exhaust pipeline (7), the inner pipeline (8) and the outer pipeline (9) form an integrated structure, and the air exhaust pipeline (7) is of a foldable coiled structure.

4. A vacuum glass evacuation device as claimed in claim 1, wherein: inner tube (8) and extraction opening (3) constitute sliding construction, and inner tube (8) constitute through connecting block (14) and metal sprue (15) and dismantle mounting structure to connecting block (14) set up to have elastic metal material, and the junction of connecting block (14) and inner tube (8) sets up to the inclined structure simultaneously.

5. A vacuum glass evacuation device as claimed in claim 1, wherein: glue injection ports (16) are arranged at the bottom ends of the outer pipelines (9) at equal angles, the outer pipelines (9) and the glue injection pipes (10) form an integrated structure, and the glue injection pipes (10) are made of flexible graphite packing materials.

6. A vacuum glass evacuation device as claimed in claim 1, wherein: the transmission gear (12) is meshed with the transmission sliding plate (13), the transmission sliding plate (13) and the machine body shell (1) form a sliding structure, and the transmission sliding plate (13) and the outer pipeline (9) form an integrated structure.

7. A vacuum glass evacuation device as claimed in claim 1, wherein: the diameter of the metal block (15) is the same as that of the air pumping opening (3), and the height of the metal block (15) is smaller than the depth of the air pumping opening (3).

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